[Assessment of immunogenic activity of the cloned human rotavirus A WA strain.]

INTRODUCTION: Rotovirus infection (RVI) caused by the dsRNA-containing virus from genus Rotavirus, Reoviridae family, belonging to group A (RVA), is the cause of severe diarrhea in human and other mammalian species. Vaccination is the most effective way to reduce the incidence of RVI. At present, the effectiveness of using gnotobiotic piglets as a universal model for reproducing human rotavirus infection and assessing the quality of RVI vaccine preparations has been experimentally proven. OBJECTIVES: Evaluation of immunogenic activity of the cloned RVA Wa strain in the new-born Vietnamese potbellied piglets trial. MATERIAL AND METHODS: Development of viral preparations of the cloned human Wa strain PBA, development of human RVA rVP6, ELISA, polymerase chain reaction with reverse transcription, immunization and experimental infection of newborn piglets. RESULTS: The article presents the results of the experiment on double immunization of newborn piglets with native virus preparations with the infection activity 5.5 lg TCID50/ml, 3 cm3 per dose, HRV with adjuvant 500 µg per dose and mock preparation (control group) followed with experimental inoculation of all animals with virulent virus strain Wa G1P[8] human RVA with infectious activity of 5.5 lg TCID50/ml in 5 cm3 dose. Development of clinical signs of disease and animal death were observed only in control group. RT-PCR system to detect RVA RNA in rectal swabs, samples of small intestine and peripheral lymph nodes was developed. ELISA based on obtained human RVA rVP6 was developed and results on RVA-specific IgG-antibodies in serum samples of experimental piglets are presented. CONCLUSION: In the course of the research, a high immunogenic activity of the native and purified virus of the cloned Wa RVA strain Wa was established and the possibility of its use as the main component of the RVI vaccine was confirmed. The possibility of using conventional newborn pigs instead of gnotobiotic piglets as an experimental model was demonstrated.

[Effects of nifedipine on the mechanical properties of sarcolemma and modulation of calcium accumulation dynamics in fibers of the rat soleus muscle under short-term hypogravity conditions].

It has been shown that the modulation of the mechanical properties of sarcolemma by nifedipine may be related to the dynamics of accumulation of calcium ions under short-term rat hindlimb suspension. The basal calcium level was measured by the fluorescence probe Fluo-4AM, the transversal stiffness of different parts of the contractile apparatus and sarcolemma was estimated by atomic force microscopy, and the content of desmin was determined by gel electrophoresis with immunoblotting. It has been found that nifedipine has a protecting effect on muscle fibers under hypogravity by decreasing the degradation of desmin and proteins that determine the transversal stiffness of sarcolemma and the contractile apparatus, and the intensity of the increase in the basal calcium level. It was shown that the selective blocking of L-channels leads to an increase in the basal calcium level in intact soleus fibers. At the same time, the transversal stiffness of sarcolemma and the contractile apparatus increased. The mechanism of this increase is still unclear; however, it is assumed that it mediates the protecting action of nifedipine.

[Dynamics of calcium levels and changes SERCA content in muscle fibers of rats and Mongolian gerbils during hind limb unloadings of various duration].

In this study, it was shown that calcium levels in the fibers of m. soleus of Mongolian gerbils after one day of unloading increased four and a half times in comparison with the control. In rats, the situation differed: 2.8 times increase after the 1st day of hypogravity persisted until the 3rd day and then calcium levels slightly decreased to the 12th day. However, the base concentrations of calcium in the control group of gerbils were significantly lower than in control rats, thus there was larger shift of this parameter during the first day. Probably, this was the reason for an earlier start of the protein phenotype shift in gerbils: statistically significant increase in the number of fibers with "fast" SERCA isoforms was detected after one day of unloading and therefore slow-to-fast shift in myosin phenotype was observed on the 3rd day of unloading. The same changes in rat muscle could be detected only after the 7th and the 12th day, respectively. In both species, there was a tendency to restore their initial parameters to the 12th day but in gerbils it was much more intensive.

[Electrogenic activity of Na-K-ATPase and calcium ions in m. soleus fibers of rats and Mongolian gerbil during simulation of gravitational unloading].

Some of the electrophysiological parameters of m. soleus of rat and Mongolian gerbil, and Ca ions content in fiber myoplasm were compared in different periods of gravitational unloading simulated by tail-suspension. No difference was found between the control animals as for membrane potential at rest, electrogenic activities of Na-K-ATPase and its isoforms, and input resistance of m. soleus fibers. At the same time, unlike rats, gerbils exhibited a substantial Ca decrease in myoplasm. From day one to 14 of gravitational unloading the pace of electrophysiological changes in gerbil's m. soleus was noticeably slower than of rat's, whereas Ca ions depositing in myoplasm was observed in both species already at the beginning ofsuspension. Analysis of the results suggests that adaptive changes in m. soleus of Mongolian gerbil and rat during simulated gravitational unloading are fundamentally different due to, probably, peculiar water-electrolyte metabolism, type of locomotion, and other factors which are still unclear.

[Comparative analysis of structural and functional characteristics of soleus muscle in rats and Mongolian gerbils during gravitational unloading of various duration].

A comparative investigation of the dynamics of contractile properties of the whole soleus muscle and its fibers during 3- and 12-day-long hind limb suspension of Wistar rats and Mongolian gerbils (Meriones unguiculatus) has been performed. The data obtained indicate that the structural and functional changes caused by hypogravity in gerbils are slowed down compared with rats. A very intensive drop in water containment in gerbils was found, which can cause shifts in the ionic strength of the intracellular space of the muscle fiber. As a result, the photolytic activity of different enzymes may change, which can induce a less pronounced reduction in Z-disc and M-line stiffness and contractile capabilities in gerbils compared to rats.

[The cellular effects of functional unloading and passive stretch on m. soleus of dystrophin-deficient mdx mice].

Dystrophin, subsarcolemmal protein communicating muscle fiber cytoskeleton to extracellular matrix, is believed to participate in mechanical signal transduction. Recent works testify possible signaling role of this protein to prevent development ofproteolytic processes accompanying muscle fiber atrophy and to stimulate the passive stretch anabolic effects. The experiment was carried out to assess the role of dystrophin in these processes. The study was performed on two months old C57 black and mdx (dystrophin-deficient) mice. Passive stretch resulted in attenuating atrophy development in two fiber types of both C57 black and mdx mice, at the same time fiber type slow-to-fast transformation did not occur in mdx soleus. We established ablatitious effect of chronic hindlimb unloading on SC proliferative activity in soleus muscle and drastic increase of proliferation under effect of passive stretch. We observed no relationship between altered dystrophin synthesis and satellite cell proliferation activity in soleus muscle under conditions of simulated microgravity and concurrent passive stretch. It is concluded that altered dystrophin synthesis partly retarded slow myofibers atrophy and had virtually no effect on passive stretch preventive action. Thus, the hypothesis about dystrophin key role in downregulation of atrophy signaling mechanisms has not found its confirmation concerning gravitational unloading atrophy.

The role of L-type calcium channels in the accumulation of Ca2+ in soleus muscle fibers in the rat and changes in the ratio of myosin and serca isoforms in conditions of gravitational unloading.

Gravitational unloading is known to produce changes in the expression of a number of contractile and regulatory proteins in the soleus muscle. This applies particularly to isoforms of myosin heavy chains (MHC) and SERCA sarcoplasmic reticulum calcium pumps. Unloading increases the resting levels of extracellular calcium in soleus muscle fibers. The present study addresses verification of the hypothesis that changes in the expression of MHC and SERCA isoforms in gravitational unloading are linked with the accumulation of calcium ions in the myoplasm of muscle fibers. It is suggested that specific blockade of L-type calcium channels using nifedipine decreases the myoplasmic calcium ion concentration, thus preventing the development of changes in the expression of MHC and SERCA isoforms. A total of 36 male Wistar rats were divided into three groups: a control group, an unloading group using the Morley-Holton soleus muscle functional unloading model, and an unloading + nifedipine group, where animals received daily nifedipine (7 mg/kg/day) with their drinking water on the background of suspension. The results showed that blockade of L-type calcium channels on the background of gravitational unloading significantly decreased the extent of calcium ion accumulation in the myoplasm of soleus muscle fibers, which partly prevented the transformation of muscle fibers (in relation to the fast and slow isoforms of MHC and SERCA) to the rapid type. There was no nuclear translocation of the greater part of transcription factor NFATc1, as seen on unloading.

[Decrease in the electrogenic contribution of Na,K-ATPase and resting membrane potential as a possible mechanism of calcium ion accumulation in filaments of the rat musculus soleus subjected to the short-term gravity unloading].

After three days of hind limb unloading, the depolarization of muscle fibers from -71.0 +/- 0.5 mV to -66.8 +/- 0.7 mV as well as a decrease in muscle excitability and a trend to fatigue acceleration were observed. After hind limb unloading, the electrogenic contribution of the ouabain-sensitive alpha2 isoform of Na,K-ATPase, tested as depolarization due to the administration of 1 microM ouabain, decreased from 6.2 +/- 0.6 to 0.5 +/- 0.8 mV. The contribution of the ouabain-resistant alpha1 isoform, estimated as additional depolarization after the administration of 500 microM ouabain, decreased from 4.6 +/- 0.6 to 2.6 +/- 0.6 mV. After hind limb unloading, the fluorescence intensity of single muscle fibers loaded with Fluo-4-AM increased more than four times, indicating an increase in intracellular Ca2+ concentration. The effect was prevented by local delivery of nifedipine, which blocks L-type Ca2+ channels. These data suggest the existence of a selective mechanism of suppression of the alpha2-pump electrogenic contribution, which led to the depolarization of soleus muscle fibers after 3 days of hind limb unloading. The depolarization in turn may activate L-type Ca2+ channels, resulting in intracellular Ca2+ accumulation.

[Contractile properties of the isolated rat musculus soleus and single skinned soleus fibers at the early stage of gravitational unloading: facts and hypotheses].

The contractile properties of the postural rat soleus muscle at the early stage of the gravitational unloading (3-day rat hindlimb suspension) have been studied using different modes of muscle contraction (twitch and tetanic contraction of the isolated muscle, Ca-induced contraction of isolated skinned fibers). A significant enhancement of the twitch maximal tension of unloaded muscles without changes in time-dependent characteristics was observed, although the half-relaxation time tended to increase. The fiber diameter did not change (42.37 +/- 0.76 vs 43.43 +/- 1.15 microm in controls). The Ca-induced maximal isometric tension in unloaded soleus was significantly decreased (32.1 +/- 1.05 vs 37.6 +/- 1.52 mg in controls, p < 0.05). The maximal specific tension was respectively decreased (23.14 +/- 0.77 vs 27.6 +/- 2.36 kN/m in controls). The pCa50 in unloaded muscle decreased from 6.05 +/- 0.02 in controls to 5.97 +/- 0.02 (p < 0.05), indicating the loss of myofibrillar calcium sensitivity. The analysis with the calcium probe Fluo-4AM demonstrated that the intracellular [Ca2+] was sufficiently increased after hindlimb suspension. At the same time, the relative content of titin and nebulin did not change.

Muscle progenitor cell proliferation during passive stretch of unweighted soleus in dystrophin deficient mice.

Dystrophin, subsarcolemmal protein communicating muscle fiber cytoskeleton to extracellular matrix, is believed to be involved in mechanical signal transduction. The experiment was carried out to assess the role of dystrophin in passive stretch-induced preventing unloaded muscle fiber atrophy and possible linkage between this protein and muscle progenitor (satellite cells) proliferation activity. The study was performed on two months old C57 black and mdx (dystrophin-deficient) mice. Passive stretch resulted in attenuating atrophy development in two fiber types of both C57 black and mdx mice. Altered dystrophin synthesis in mdx mice had virtually no effect on passive stretch preventive action. Thus the hypothesis about dystrophin key role in mediating stretch-induced hypertrophy effects didn't find its confirmation concerning gravitational unloading atrophy. Chronic hindlimb unloading downregulated SC proliferative activity in soleus muscle, passive stretch drastically increased proliferation both in C57 and mdx mice. Thus we observed no relationship between altered dystrophin synthesis and satellite cell proliferation activity in soleus muscle under conditions of simulated microgravity and concurrent passive stretch.

[Role of L-type Ca channels in Ca2+ accumulation and changes in distribution of myosin heavy chain and SERCA isoforms in rat M. soleus under gravitational unloading].

It is known that hindlimb unloading brings about the intracellular Ca2+ accumulation and MyHC slow-to-fast shift in m.soleus. SERCA (sarcoendoplasmatic reticulum Ca ATPase) function as a Ca pump to uptake to sarcoendoplasmatic reticulum after skeletal muscle contraction, and can modulate intracellular resting Ca level. The study was aimed at investigation of the role of intracellular Ca2+ level for MyHC and SERCA isoforms transformation in m.soleus under hindlimb unloading. To determine role of intracellular Ca we administrated nifedipin--specific blocker of L-type calcium channel in myofibers. We hypothesized that decrease of intracellular calcium level prevented-NFATc1 nuclear translocation and MyHC slow-to-fast transformation. 42 male Wistar rats (180-200 g) were divided in 3 groups: cage control (C, n = 14), 14 days HU (HU, n = 14), 14 days HU with 7 mg/kg/day of nifedipin administration with water (HUN, n = 14). The study has shown that increase of intracellular Ca2+ level under HU leads to MHC slow-to-fast shift via activation of calcineurin-NFATc1 signaling pathway. Percentage of muscle fibers with SERCA I increased under hindlimb unloading, being dependent of intracellular calcium level, percentage of muscle fibers with SERCA II decreased under hindlimb unloading but did not depend on calcium. We suppose that nifedipin administration decreases intracellular Ca level, prevents MHC slow-to-fast shift via prevention of NFATcl accumulation in nuclear extract of m.soleus, and prevent increase of SERCAI expression. The work was supported by grants RFBR N05-04-49255a, 04-04-49044, 05-04-08200-ofi-a, contract with Federal Agency for Science and Iinnovation N02.467.11.3005, and Presidium of RAS program "Basic sciences for medicine".